Entropy-Based Multifractal Testing of Heart Rate Variability during Cognitive-Autonomic Interplay.

IF 2.1 3区物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY

Entropy Pub Date : 2023-09-21 DOI:10.3390/e25091364

Laurent M Arsac

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Abstract

Entropy-based and fractal-based metrics derived from heart rate variability (HRV) have enriched the way cardiovascular dynamics can be described in terms of complexity. The most commonly used multifractal testing, a method using q moments to explore a range of fractal scaling in small-sized and large-sized fluctuations, is based on detrended fluctuation analysis, which examines the power-law relationship of standard deviation with the timescale in the measured signal. A more direct testing of a multifractal structure exists based on the Shannon entropy of bin (signal subparts) proportion. This work aims to reanalyze HRV during cognitive tasks to obtain new markers of HRV complexity provided by entropy-based multifractal spectra using the method proposed by Chhabra and Jensen in 1989. Inter-beat interval durations (RR) time series were obtained in 28 students comparatively in baseline (viewing a video) and during three cognitive tasks: Stroop color and word task, stop-signal, and go/no-go. The new HRV estimators were extracted from the f/α singularity spectrum of the RR magnitude increment series, established from q-weighted stable (log-log linear) power laws, namely: (i) the whole spectrum width (MF) calculated as α_max - α_min; the specific width representing large-sized fluctuations (MF_large) calculated as α₀ - α_q+; and small-sized fluctuations (MF_small) calculated as α_q- - α₀. As the main results, cardiovascular dynamics during Stroop had a specific MF signature while MF_large was rather specific to go/no-go. The way these new HRV markers could represent different aspects of a complete picture of the cognitive-autonomic interplay is discussed, based on previously used entropy- and fractal-based markers, and the introduction of distribution entropy (DistEn), as a marker recently associated specifically with complexity in the cardiovascular control.

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认知自主交互过程中心率变异性的基于熵的多重分形检验。

基于熵和基于分形的心率变异性度量丰富了心血管动力学的复杂性描述方式。最常用的多重分形测试是一种使用q矩来探索小尺寸和大尺寸波动中的一系列分形标度的方法，它基于去趋势波动分析，该分析考察了测量信号中标准偏差与时间尺度的幂律关系。基于bin（信号子部分）比例的Shannon熵，存在对多重分形结构的更直接的测试。这项工作旨在使用Chhabra和Jensen在1989年提出的方法，重新分析认知任务中的HRV，以获得基于熵的多重分形谱提供的HRV复杂性的新标记。28名学生在基线（观看视频）和三项认知任务（Stroop color and word task、stop signal和go/no-go）中获得了节拍间持续时间（RR）时间序列。新的HRV估计量是从RR幅度增量序列的f/α奇异性谱中提取的，该奇异性谱是根据q加权稳定（对数-对数线性）幂律建立的，即：（i）计算为αmax-αmin的全谱宽度（MF）；表示大尺寸波动的比宽（MFlarge），计算为α0-αq+；和计算为αq-α0的小尺寸波动（MFsmall）。作为主要结果，Stroop期间的心血管动力学具有特定的MF特征，而MFlarge则相当特定于去/不去。基于先前使用的基于熵和分形的标记，以及分布熵（DistEn）的引入，讨论了这些新的HRV标记可以代表认知自主相互作用的完整画面的不同方面的方式，该标记最近与心血管控制的复杂性特别相关。

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来源期刊

Entropy PHYSICS, MULTIDISCIPLINARY-

CiteScore

4.90

自引率

11.10%

发文量

1580

审稿时长

21.05 days

期刊介绍： Entropy (ISSN 1099-4300), an international and interdisciplinary journal of entropy and information studies, publishes reviews, regular research papers and short notes. Our aim is to encourage scientists to publish as much as possible their theoretical and experimental details. There is no restriction on the length of the papers. If there are computation and the experiment, the details must be provided so that the results can be reproduced.